ssp 507
TRANSCRIPT
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Service Training
Self-Study Programme Technology 507
Amarok 2012The 8-speed automatic gearbox 0CM Design and function
Commercial Vehicles
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The 8-speed automatic gearbox in the Amarok
With a combustion engine, it is necessary to have a moving-off element that permits rotation speed differences between the engine speed and drivelines speed. In contrast to manual gearboxes and increased gearboxes, a 2new developments! The content will not be updated.
Important noteThe self-study programme presents the design and function of
Current testing, setting and repair instructions canbe found in the provided service literature.converter operates with almost no wear, because the powerflow is only via the gearbox when moving off. The advantages of the converter are thus its low wear and the fact that its design causes the torque to be boosted beyond the engine torque. Specifically for the Amarok, the converter therefore represents the ideal moving-off element, because the very low ratio and torque increase provide a significant improvement in off-road and towing properties. This is in comparison to the Amarok with a manual gearbox, without step-down box. After the moving-off phase, the hydraulic slip of the converter is eliminated by the controlled lock-up clutch. This improves efficiency significantly.
Key data
- Engine: 2.0 l bi-TDI with 132 kW- Gearbox: 0CM- can be combined with start/stop system
The automatic gearbox in the Amarok is a completely newly developed 8-speed automatic gearbox, in which the greatest importance has been placed on efficiency, gearshift comfort and speed, low weight and reliability. The gearshifts are performed without interruption in traction, and the gearshift speeds are at the level of a DSG.
S507_003
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At a glance3Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4The driveline. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 The transfer box. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Design features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6The 8-speed automatic gearbox 0CM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 The new 2.0 l 132 kW TDI engine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Selector lever . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8The selector lever module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 The selector lever actuation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 The ignition key removal lock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 The selector lever emergency release . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Gearbox structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12The overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 The torque converter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 The oil supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 The planetary gearbox . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Gearbox management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22The mechatronic unit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22 The sensors. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 The actuators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Gearbox function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .26The hydraulic interfaces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 The start/stop system. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 The hydraulic pulse accumulator (HPA) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Service. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32The special tool . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 The gearbox adaptation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
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Introdu
The dThe Amadrive, trafor the Aon any s
Conne
Transferdistribut
The ATFsteel. Th(ATF = A4Transfer boxATF filler and inspection plugElectricalconnector
ATF drain plugIntermediate plate
Automatic gearbox
The intermediate plate prevents dirt from getting in between the automatic gearbox and the transfer box.ction
rivelinerok has a modular driveline in which the individual components such as automatic gearbox, front final nsfer box and rear final drive are each independent modules. The drive combination designed especially marok comprising permanent four-wheel drive and an automatic gearbox is configured for ideal traction urface.
ction of transfer box to automatic gearbox
box with self-locking centre differential and variable torque ion.
drain plug is located at the bottom of the oil pan made from sheet e ATF filler and inspection plug is located on the side of the housing utomatic Transmission Fluid).
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5S507_005Gearbox ventilationThe transfer boxThe design of the transfer box installed in the Amarok with a self-locking centre differential is based on the transfer box in the Audi Q7 and the Touareg 2011. It has been adapted for use in the Amarok.
Characteristics
Modern "four-wheel drive" technology in the Amarok Sturdy system that operates purely mechanically Suitable for onroad and offroad use Permanent four-wheel drive Differential compensation between the front and rear axles Full ESP suitability in four-wheel drive and locked-up rear axle differential
For more information, refer to SSP 464.
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De6emergency mode, for example, allows the vehicle to continue to be driven in 6th and reverse gear even if there is a total electrical failure of the mechatronic unit, until the engine is switched off or the selector lever is moved to the "P" position.Achieving maximum speed in 7th gear
Operating modes Automatic, S and Tip
Gear ratios 8 forward gears, 1 r
Spread 7.071
First fill by manufacturer approx. 9 l
Fill volume of ATF cooling system approx. 0.6 l
Emergency running properties The emergency runntechnical possibilitiesreadiness is guaranttronic mode
everse gear
ing and default programmes are state-of-the-art as far as are concerned, meaning that a high level of operational eed even in the case of a fault. The hydro-mechanical sign features
The 8-speed automatic gearbox 0CM
- Two-damper converter- Lightweight construction by design measures- 1st gear as a short moving-off gear for offroad
driving and towing a trailer. (No additional low-range box required.)
- 8th gear with a longer ratio for reducing the engine speed and fuel consumption.
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Technical data
Developer/manufacturer ZF Friedrichshafen AG
Designation at ZF: 8HP45at VW: AL450-8Ain Service: Automatic gearbox 0CM
Gearbox features Electrohydraulically controlled 8-speed planetary gearbox with hydrodynamic torque converter and torque converter lock-up clutch with controlled slip.
Control Mechatronic unit (integration of the hydraulic control unit with the electronic control unit to make a single unit).
Torque max. 450 Nm
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i7Torque [Nm]
Power [kW]
S507_0800 01000 2000 3000 4000 5000 [rpm]Engine code CSHACubic capacity 1968 cm3
Number of cylinders 4Bore 81.0 mmStroke 95.5 mmValves per cylinder 4Compression ratio 16.0:1Max. power 132 kW at 4000 rpmMax. torque 420 Nm at 1750 rpmEngine management EDC 17CP 20Turbocharging BiturboExhaust gas recirculation YesDiesel particulate filter Euro 5/PL6Emissions standard Euro 3/4/5/PL6400
350
300
250
200
150
100
50
[Nm]
80
60
40
20
[kW]
100
120
450
140
160
180The new 2.0 l 132 kW TDI eng
Special features
Biturbo Common rail injection system with solenoid valve
injectors Controlled EGR cooling system Torque adapted to the automatic gearbox
The new 132 kW TDI engine will be used together with the 8-speed automatic gearbox.
Technical data ne
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Power and torque curve
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Se8- Selector lever lock (P/N lock)S507_008
Selector lever cable
The selector mechanism operates using the selector lever module. It has both a mechanical connection to the automatic gearbox via a cable and an electrical connection to the gearbox control unit. The drive range is selected by the cable. Only the special drive programmes Manual (tip) and S are sent to the gearbox control unit by the selector lever electronic control unit by means of a modulated square-wave signal.
Functions of the cable connection
- Operation of the parking lock- Operation of the selector slide of the hydraulic
control unit in the mechatronic unit- Operation of the gear sensor in the gearbox
Electric functions
- Ignition key removal lock- Activation of the selector lever position display (via
gearbox control unit)- Tiptronic functionSelector lever sensor unitJ587
lector lever
The selector lever moduleSelector lever locked in position P switchF319
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9 For more information about the selector lever lock solenoid, refer to SSP 454, pages 8 and 9.energised and unlocked. In driver range "N" it is energised and locked.moving automatically and stops the parking lock from being unlocked.
After the ignition has been switched on and the brake pedal is pressed then the gearbox control unit energises the solenoid N110. This means the locking pin is withdrawn from the locking pin trap "P". The selector lever can now be moved into the drive position. Once the selector lever has left position "P", the magnet is de-
S507_010
Locking pin trap for "P"
Locking pincorresponding light-emitting diode on the display unit Y6.
Selector lever lock solenoid N110
Solenoid N110 blocks the selector lever in positions "P" and "N". The solenoid is controlled by the gearbox control unit. If the selector lever is in "P" in de-energised condition (ignition off) then the locking pin is in the locking pin trap "P". This prevents the selector lever from S507_011
Solenoid forselector lever lock N110 Lever for
emergency releaseerformed by tipping the selector lever backwards once out ck into the D/S position. When the selector lever is tipped
it J587 sends the tip signal to the gearbox control unit. In e S takes place, or back to driving program D. This makes
cial gearshift programme S and from the normal driving
ted for offroad driving)
Selector lever position display Y6
Information about the selector lever position comes directly from the gearbox control unit as a modulated square-wave signal. The selector lever sensor unit in the selector lever evaluates the signal and activates the The selector lever actuation
The change from drive ranges D to S (or from S to D) is pof the D/S position. The selector lever always springs baback from the D/S position, the selector lever sensor unresponse, the changeover to special gearshift programmit possible to reach the Tiptronic gate both from the speprogramme D. (Special gearshift programme S - shift programme adap
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Se10S507_013
The ignition key removal lock prevents the ignition key from being removed when the parking lock is not engaged. It functions electromechanically and is locked in "P" by the selector lever switch F319.
When switch F319 is closed, the solenoid for the ignition key removal lock N376 is energised and presses the locking pin against the spring force into the locking position. In the locking position, the locking pin prevents the ignition key from being removed.
The "selector lever locked in position P switch" does not open until the selector lever is moved into the park position, and the selector lever electronic control unit de-energises the solenoid. Following this, the locking pin is pushed back by the compression spring. The ignition key can be turned further and withdrawn.
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J587
F319
N376N376lector lever
The ignition key removal lock
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M
e
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to 11Towing
If it is necessary to tow a vehicle that is fitted with an 0Cgearboxes must be observed:
- Engage selector lever position "N", which may requirlever.
- Do not exceed the towing speed of 50 km/h.- Do not exceed the maximum towing distance of 50 km
The rear axle differential lock is not allowed S507_016
gearbox then the usual restrictions for automatic
using the emergency release function of the selector
be engaged at any time during towing.The selector lever trim must be removed in order to operate the emergency release for selector lever lock.
The emergency release lever is located on the right side of the selector mechanism. When the emergency release lever is operated, the locking pin of the solenoid N110 is pushed against the spring force (see Fig. S507_010, page 9). The selector lever interlock button must be operated at the same time in order to unlock the selector lever.
Selector lever interlock buttonThe selector lever emergency release
Mechanical emergency release makes it possible to move the selector lever if the electrical power supply fails.
Lever for emergency release
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Ge12Output shaft with splines
Transfer box
Electrical connector
ATF filler and inspection plug
Planetary gearbox with selector elements
Output flange
arbox structure
The overview
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31S507_017
Mechatronic unit
Torque converter
Front final drive
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Ge14The torque converter lock-up clutch pressure is closed by pressure regulating valve 6 N371 and the corresponding hydraulic control valves in the mechatronic unit.Effective damping systems and exact control of the torque converter lock-up clutch permit a further minimization in the torque converter slip even from 1st gear.
Neutral idle control ensures that the converter torque loss is reduced even when the vehicle is stationary in drive range "D".S507_018
Stator shaft
Converter centring
Splines forinput hub - ATF pump
ATF pump
Brake A
Sun gear shaft S1/S2
Drive hub for the ATF pump Splines and chain sprocket
Piston brake B
Toothed chain
Torsion damperarbox structure
The torque converterA torque converter with torsion dampers is used for effectively damping the torsional vibrations of the engine. It is a "two-damper torque converter" with a torque converter lock-up clutch. Basic information about how torque converters function can be found in SSPs 300 and 309, amongst others.
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51intake port.ATF pump
One of the most important components of an automatic gearbox is the ATF pump. It has the special features of a side-by-side arrangement with parallel shafts, and the chain drive. The ATF pump is a highly efficient, double-stroke vane pump.
The ATF pump sucks in the ATF through a filter and channels the pressurised oil to the system pressure valve in the hydraulic gearshift unit of the mechatronic unit. This is where the system pressure for operating the gearbox is set. If too much oil is pumped then the excess is returned to the ATF pump in a hydrodynamically efficient fashion in the
S507_020Return of excess pumped oil
ATF pan ATF suction filter
To the ATF pump
Sleeve with channel for direct, flow-correct return to the ATF pump
System pressure valve
From ATF suction filterThe oil supply
System pressure - to the hydraulic valves
System pressure - to the torque converter pressure valve
Control pressure - from pressure regulating valve 7 N443
System pressure valve
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Ge16from the thermostat and from the cooler in order to rinse the individual components. Make sure that all impurities are cleaned out. If in doubt, renew components such as the ATF cooler or thermostat. Residual impurities will result in further complaints and/or damage to the gearbox! Please always comply with the relevant valid workshop manual!S507_021
Oil temperature controller (thermostat)
ATF cooler supply
ATF cooler return
Oil temperature controller (thermostat)
The thermostat is integrated into the supply and return of the ATF cooling system. An expansion thermostat with integrated bypass (bypass thermostat) is used.
Please note that impurities in the ATF (e.g. abrasion, chips) will be distributed around the ATF cooling system and will be deposited there. If necessary, the cooling system must be rinsed carefully during a gearbox repair or prior to a gearbox renewal. For this purpose, it is necessary to remove the lines ATF coolerarbox structure
Oil cooling / ATF cooling
ATF cooling takes place with thermostat control by means of an oil/air heat exchanger (ATF cooler). The ATF cooler is positioned in front of the radiator and in front of the condenser, as seen in the direction of travel.
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71ATF temperature must be raised to at least 90 C by a test drive in order for the ATF level to be set correctly. This ensures that the ATF cooler is filled. Set the ATF level after cooling down to the normal test temperature (see Workshop Manual).Thermostat opened
G = from or to gearbox K = from or to radiator
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G K
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Cover Plunger
K
K
G
G
Impurities can block the bypass of the thermopreventing it from functioning. This can resultof 25 C and during normal driving, the ATF
If the cooling system was opened during a rethe spring force. This opens up the flow to the cooler (see next fig.).
The thermostat is fully open from a temperature of about 90 C onwards.
stat, thereby disrupting the function of the thermostat or in the gearbox overheating! At an ambient temperature temperature will scarcely ever exceed 110 C.
pair (meaning that the ATF cooler is drained) then the Thermostat functionThermostat closed
Bypass Expansion element
G K
The expansion element is also the valve element of the thermostat and regulates the flow into the cooler.
In closed condition, a small amount of ATF always flows through the bypass as a result of which the expansion element is warmed up.
From a temperature of about 75 C onwards, the plunger starts to push the expansion element downwards against
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Ge18open.
When achieving the individual gears, three selector elements are always closed and two selector elements are The multi-plate clutches C, D and E transmit the engine power into the planetary gearbox. The multi-plate brakes A and B brace the torque against the gearbox housing.
to its starting position. The function of the selector elements is to carry out the gearshifts under load, as well as without any interruption in traction.Brake A
Brake B
PT1PT3
RS2
RS1
RS3
Clutch E
Clutch C
ATF pump
The 8 forward gears and the reverse gear are created by corresponding link-ups between four single planetary gearboxes. The two gear sets at the front have a shared sun gear. The output is always via the planet carrier of the 4th gear set.
The planetary gearbox
The selector elements, clutches and brakes are hydraulically closed. Oil pressure forces the clutch pack together and causes the clutch to be engaged for power transmission. If the oil pressure drops, the dished washer in contact with the piston forces the piston back
Selector elements
Only 5 selector elements shift 8 gears!- 2 multi-plate brakes A and B- 3 multi-plate clutches C, D and Earbox structure
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not show91ar display of the selector elements lanetary gearboxes, some parts are
n.S507_072
speed-dependent pressure build-up in the clutch. This compensating effect is achieved by a second piston space, called the pressure equalisation space. The advantages of dynamic pressure equalisation are:
- Reliable opening and closing of the clutch in all speed ranges- Improved gearshift comfort
For detailed information about the brakes and clutches, refer to SSP 457 page 27.Braking
For a cleand the p
RS4
Clutch D
Brake A is equipped with a return spring. Brakreturn spring; this function is carried out by a s
Brake B is operated with slip in neutral idle conthe requirements of neutral idle control on a suhydraulic gearshift unit when activated.
Clutches
Clutches E, Cmeans oil pr
Legend for p
RS1 to 4PT1 to 4S1 to 4P1 to 4H1 to 4 and D are balanced with regard to the dynamic pressure. This essure acts on both sides of the clutch piston in order to avoid a
Sun gear of planetary gearbox 1 to 4Planetary gears of planetary gearbox 1 to 4Annulus of planetary gearbox 1 to 4e B has a special design. The piston of brake B does not have a econd piston space.
trol. The size of brake B has been selected to enable it to withstand stained basis. In addition, it receives specific cooling from the
lanetary gearbox
Planetary gearbox 1 to 4Planet carriers 1 to 4
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Ge20RS1 S507_068RS2 RS3 RS4OutputPT1 to 4 Planet carriers 1 to 4S1 to 4 Sun gear of planetary gearbox 1 to 4P1 to 4 Planetary gears of planetary gearbox 1 to 4H1 to 4 Annulus of planetary gearbox 1 to 4
H1
P1
S1
H2
P2
S2
H3
P3
S3
H4
P4
S4PT1
PT2
PT3
PT4
The ratios in the individual gears are obtained by inputting the torque via various elements of the planetary gearbox while other elements are braked.S507_035Brake A
Brake B
Clutch E
Clutch C
Clutch DTorque converter
Legend for planetary gearbox
RS1 to 4 Planetary gearbox 1 to 4RS1RS2
RS3 RS4
arbox structure
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12Brake B is open in neutral idle control except for a small residual torque.2) Brake B is open in P and N positions except for a small residual torque.X Active (control current depends on operating condition)
1)S507_067
7th gear
8th gear
Brake closed Clutch closed
Pressure regulating valves (EDS electric pressure regulating valve)
1 Active0 Not active (a low basic control current is always present)4th gear
5th gear
6th gearSelector elements / pressure regulating valves
Parking lock
EDS-AN215
EDS-BN216
EDS-CN217
EDS-DN218
EDS-EN233
EDS-WKN371
EDS-SysN443
3rd gear
2nd gear
1st gear
R gear
Neutral
2)
1)
2)
Spread: 7.071
S507_066
Gearshift matrixGear step:
Ratio:
gear: 1st 2nd 3th 4th 5th 6th 7th 8th R
4.7 3.14 2.11 1.67 1.29 1 0.84 0.67 -3.33
1.5 1.49 1.26 1.3 1.29 1.19 1.25
The mechanical ratio is divided up as follows (values are rounded):
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Ge
ce22When installing the mechatronic unit, make sure that the gearbox selector lever engages in the groove of the slide block and the selector slide (see Fig. S507_030).discharge. Please comply with the specifications and instructions in SSP 284 (page 6) and in the Workshop Manual. N215 Pressure regulating valve 1 (EDS-A)N216 Pressure regulating valve 2 (EDS-B)
N371 Pressure regulating valve 6 (EDS torque converter lock-up clutch)
N443 Pressure regulating valve 7 (EDS system pressure)
Particular care must be taken to ensure that the electronics are protected against electrostatic S507_030
N88
N443
N233
N371
N217
N216
G195
G676
Parking lock latch with spring
Linkage
Gearbox selector lever
Slide block
G195 Gearbox output speed senderG676 Gear sensorN88 Solenoid valve 1 (MV-Pos)
N217 Pressure regulating valve 3 (EDS-C)N218 Pressure regulating valve 4 (EDS-D)N233 Pressure regulating valve 5 (EDS-E)element has its own electric pressure regulating valve alldynamics and to implement a variety of gearshift sequen
N218
N215ated to it, in order to achieve a high level of gearshift s.
Selector slidearbox management
The mechatronic unitThe mechatronic unit is the central control unit of the gearbox. It consists of the hydraulic control unit with solenoid and pressure regulating valves, and the electronic module with sensors and the gearbox control unit. Each selector
oc
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32
S507_025 Conical slide with springParking lock latchcheck and carry out the following points:
- Code the control unit- Adaptation of the selector lever position display- Adaptation of the selector element
Parking lock
The parking lock is operated via the selector lever cable. If the selector lever is pushed into position P, the gearbox selector lever pushes the linkage on the end of which the conical slide with the spring is located. The cone pushes the parking lock latch onto the parking lock gear.
Gearbox selector leverRenewing the mechatronic unit
When renewing the mechatronic unit, make sure that the control unit and electronic components are not damaged by electrostatic discharge. Following an update of the gearbox software or after the mechatronic unit is renewed,
S507_031
Gear sensor G676
E-module Gearbox output speed sender G195Suction connection to ATF puCompressed air connection from the ATF pumpmp
Gearbox input speed sender G182
Control unit for automatic gearbox J217
Sender for ATF temperature G93
Electrical connector to the vehicle
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Ge24electronics.rotation and adjust themselves to a change in the magnetic field strength, thereby adapting the tolerances of the air gap between the sensor and sender wheel.
Sender for ATF temperature G93
The ATF temperature sender is located on the electronic module. In conjunction with the temperature measured inside the control unit, measures are taken if necessary to protect both the gearbox mechanism and the gearbox
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input speed G182D to S or from S to D by the selector lever sensor unit J58
Gearbox input speed sender G182 and gearbox output speed sender G195
The gearbox input speed sender G182 has a sender wheel with a magnetic ring. The sender wheel is connected to the planet carrier 2. G182 records the speed of the planet carrier of the 2nd planetary gearbox (PT2). Planet carrier 2 is positively connected with the turbine shaft (turbine input speed = gearbox input speed).
The cylinder connects planet carrier 1 to annulus 4 via the magnetic ring sender wheel. The cylinder is made from a high-strength aluminium alloy. This means the material is non-magnetic, and the magnetic fields of the magnetic ring act through the cylinder on sensor G182.
Speed senders G182 and G195 are referred to as intelligent sensors. They detect the direction of arbox management
The sensorsGear sensor G676
The sensor is a component of the electronic module and is operated by the gearbox selector lever together with the selector slide. A solenoid in the slide block of the sensor switches 4 Hall sensors (A, B, C and D) according to the selector lever position. The signals of the Hall sensors are evaluated and thus provide the gearbox control unit with information about the selector lever positions P, R, N and D. The gearbox control unit is notified of the change from
7.Sender for gearbox output speed G195
Sender for gearbox
Cylinder
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The actuatorsPressure regulating valves - solenoid valv52gear position then N88 is activated accordingly by the gearbox control unit. This means the hydraulic valves in the mechatronic unit are switched so as to prevent reverse gear being engaged in the gearbox.Solenoid valve 1 - N88 (black/brown)
S507_063N88 is an electrically switched solenoid valve. It is referred to as a 3/2-way valve, which means it has 3 connections and 2 switch settings (open/closed or on/off). The N88 is controlled by the gearbox control unit and has a safety function.
If, during forwards travel, the selector lever and with it the selector slide in the mechatronic unit is moved to the reverse Pressure regulating valves 3, 4, 5, 7 (white)
S507_062Pressure regulating valves 3, 4, 5 and 7 have a decreasing characteristic. The more strongly they are energised, the lower the hydraulic control pressure.
3 N217 Pressure regulating valve 3 - clutch C4 N218 Pressure regulating valve 4 - clutch D5 N233 Pressure regulating valve 5 - clutch E7 N443 Pressure regulating valve 7 - system pressurePressure regulating valves 1, 2, 6 (orange)
S507_061es
Pressure regulating valves 1, 2 and 6 have an increasing characteristic. The more strongly they are energised, the higher the hydraulic control pressure.
1 N215 Pressure regulating valve 1 - brake A2 N216 Pressure regulating valve 2 - brake B6 N371 Pressure regulating valve 6 - torque converter lock-up
clutch
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Ge26Clutch C Brake B1CLOSED
Clutch E Brake AS507_065
Torque converter lock-up clutch Clutch DS507_064
Intake to ATF pump
Oil supply from the ATF pump Cooling brake B
from the radiator
to the radiator
Oil supply from the ATF pump
Intake to ATF pump to the radiator
Cooling brake B
from the radiator
from the torque converter
Brake B2
to the torque converterarbox function
The hydraulic interfaces
Torque converter lock-up clutch CLOSED
from the torque converter
Brake B2
to the torque converter
Clutch C
Clutch E
Clutch D
Brake B1
Brake A
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72to establish an adequate powerflow. In principle, the ATF pump could be designed to meet this requirement. However, a pump of this kind would result in completely unacceptable losses even at low engine speeds.Necessity in start/stop operation:
When the engine is stopped, the oil supply in the gearbox is non-existent. The selector elements of the corresponding gear disengage and the powerflow is interrupted. When the engine is started, the powerflow in the gearbox must be restored, and with it the moving-off readiness. For the 8-speed automatic gearbox, this means that three selector elements have got to be closed (see gearshift matrix). The oil volume pumped by the ATF pump whilst the engine is starting up is not sufficient to pressurise the selector elements within the required time, in order Installation location/connections
The installation position of the HPA (hydraulic pulse accumulator) is below the oil level. This means the HPA accumulator cannot run dry, and it always remains filled in the charged condition.
S507_051
HPAThe start/stop systemThe start/stop system presents a particular challenge for the automatic gearbox. During start/stop mode, it is necessary for the vehicle to be ready to start and move off extremely quickly. The engine and automatic gearbox must be ready to move off after about 350 ms in order to avoid any noticeable delay in moving off. The requirement cannot be met by an automatic gearbox unless it is configured accordingly or measures are taken on the oil supply. This problem is solved by what is referred to as the "hydraulic pulse accumulator" (HPA).
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Ge28Pressure HPA System pressure with HPA System pressure without HPAEngine start rpm S507_050
Moving-off readiness with HPA
Moving-off readiness without HPA
ms
barrpm
600 6
0 350 800pressure to the selector elements for force transmission within a fraction of a second. The HPA achieves the required moving-off readiness after only about 350 ms.
Comparison between moving-off readiness with and without hydraulic pulse accumulator (HPA).The hydraulic pulse accumulator has a useful volume of about 100 cm3.
S507_052
Cable set to mechatronic unit
Hydraulic connection
Solenoid for pressure accumulator N485
The HPA is a special oil volume accumulator with an electromechanical locking unit. It is used for providing arbox function
The hydraulic pulse accumulator (HPA)
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92Hydraulic pulse accumulator in drained condition.Connector
Solenoid for pressure accumulator N485
Ball detent mechanism
Steel spring
Piston spring accumulator
Cylinders
Piston
Hydraulic connection
Throttle non-return valve
S507_053Structure and function
The HPA consists of the piston spring accumulator, an electromechanical locking unit (solenoid for pressure accumulator N485) and a throttle non-return valve. The piston spring accumulator consists of a piston, cylinder and steel spring. Solenoid N485 has the task of holding the piston in a pre-stressed condition (N485 energised). The piston spring accumulator is "charged" when the engine is running. When the engine starts, solenoid N485 is de-energised and the stored oil volume is forced (discharged) into the hydraulic control unit by spring force. This means oil pressure is applied to the selector elements already when the ATF pump is just starting to pump. As a result, the HPA supports the ATF pump and ensures a lightning-fast pressure buildup. The pressure build-up by the HPA and by the ATF pump overlap at the time when the pump is delivering sufficient pressure. The charging procedure of the piston accumulator starts from this point onwards. The supply to the piston spring accumulator is restricted so that the further pressure build-up is not disrupted by the charging procedure. This task is performed by the throttle non-return valve. The charging time of about 5 seconds (at 20 C) is nevertheless very short and does not impair the start/stop operation.
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Ge30HPA fully charged, piston is at the stop.S507_056N485 energisedArmature
During charging, the piston is pushed all the way to the left. When this happens, the armature of the holding solenoid is pushed into its end position required for locking, and the air gap is closed1). The balls are pushed out for locking and the solenoid N485 cannot hold the armature so that the piston remains locked. The HPA is now ready for an engine stop.S507_055N485 energised
The piston moves beyond the ball detent mechanism.S507_054
Start of charging
When the engine is running, the piston spring accumulator is filled (charged) via the throttle bore. The charging time is about 5 seconds.
Air gapN485 energised
The piston is forced against the spring force.arbox function
Start/stop operation
System pressure
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13The magnetic force is only able to hold the magnet independently when the piston pushes the armature all the way to the left as far as the stop (see Fig. 507_056).1) The magnetic field generated by solenoid N485 is unable to pull the armature towards it against the spring force. S507_058
HPA is discharged (engine start phase)
When the engine starts, the piston is unlocked by the holding current being switched off. The piston presses the volume of oil into the hydraulic control unit to the selector elements. The throttle non-return valve opens and allows oil to flow through a large cross section.N485 de-energised
Piston unlocked, HPA drains.S507_057
N485 energised
HPA fully charged, piston locked.
HPA is charged (engine stopped)
When the engine stops, the system pressure and the pressure in the HPA both drop. The oil volume in the HPA is depressurised. The piston is now held by the ball detent mechanism
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Se
it32S507_090
Oil level check
This is performed in accordance with the workshop manual using the "Oil level check" function in the Guided Functions / Guided Fault Finding.rvice
The special toolSpecial tool for installing the mechatronic un
The guide pin T40199 means the mechatronic unit can be kept straight when being inserted. This prevents damage to the oil ducts on the rear of the mechatronic unit.
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33Irrespective of the individual adaptation values and general adaptation conditions of the 0CM gearbox, you will find detailed information about the principles of gearbox adaptation in SSP 385.
Please always comply with the relevant valid workshop manual!Adapting the 5 selector elements (brakes A, B and clutches C, D, E) during a service may be necessary in the following cases, for example:
- After the mechatronic unit has been changed- Gearbox change- Gear oil change- Deletion of the adaption values by a software update- Complaints due to harsh/raw gearshift behaviour
The adaption is performed using the vehicle diagnostic tester as part of an adaption drive. The process is specified exactly in the Guided Fault Finding or Guided Functions, and is self-explanatory.The gearbox adaptationIn order to maintain the gearshift quality at a high level over the entire service life of the gearbox, various control parameters are adapted continuously and the measured adaption values are stored. These adaptations and/or this learning process are referred to as adaption.
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Notes34
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53
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VOLKSWAGEN AG, WolfsburgAll rights reserved. Subject to technical modifications.000.2812.64.20 Technical status 01/2012
Volkswagen AG Volkswagen Nutzfahrzeuge Vertrieb After SalesAfter Sales Technik NV-K/3Brieffach 2940D-30405 Hannover
This paper was manufactured using pulp bleached without the use of chlorine.
507
StartAt a glanceIntroductionThe drivelineThe transfer box
Design featuresThe 8-speed automatic gearbox 0CMThe new 2.0 l 132 kW TDI engine
Selector leverThe selector lever moduleThe selector lever actuationThe ignition key removal lockThe selector lever emergency release
Gearbox structureThe overviewThe torque converterThe oil supplyThe planetary gearbox
Gearbox managementThe mechatronic unitThe sensorsThe actuators
Gearbox functionThe hydraulic interfacesThe start/stop systemThe hydraulic pulse accumulator (HPA)
ServiceThe special toolThe gearbox adaptation